Communication channel calibration for drift conditions

ABSTRACT

A method and system provides for execution of calibration cycles from time to time during normal operation of the communication channel. A calibration cycle includes de-coupling the normal data source from the transmitter and supplying a calibration pattern in its place. The calibration pattern is received from the communication link using the receiver on the second component. A calibrated value of a parameter of the communication channel is determined in response to the received calibration pattern. The steps involved in calibration cycles can be reordered to account for utilization patterns of the communication channel. For bidirectional links, calibration cycles are executed which include the step of storing received calibration patterns on the second component, and retransmitting such calibration patterns back to the first component for use in adjusting parameters of the channel at first component.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of co-pending U.S. patent application Ser. No. 13/846413, filed Mar. 18, 2013, entitled COMMUNICATION CHANNEL CALIBRATION FOR DRIFT CONDITIONS, which application is a continuation of application Ser. No. 13/409,534, filed 1 Mar. 2012, entitled COMMUNICATION CHANNEL CALIBRATION FOR DRIFT CONDITIONS (now U.S. Pat. No. 8,422,568), which application is a continuation of application Ser. No. 11/754,102, filed 25 May 2007, entitled COMMUNICATION CHANNEL CALIBRATION FOR DRIFT CONDITIONS (now U.S. Pat. No. 8,144,792), which application is a continuation of application Ser. No. 11/459,294, filed 21 Jul. 2006, entitled COMMUNICATION CHANNEL CALIBRATION FOR DRIFT CONDITIONS (now U.S. Pat. No. 7,415,073); which is a continuation of U.S. patent application Ser. No. 10/766,765, filed 28 Jan. 2004, entitled COMMUNICATION CHANNEL CALIBRATION FOR DRIFT CONDITIONS, now U.S. Pat. No. 7,095,789; which prior applications are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the calibration of communication channel parameters in systems, including mesochronous systems, in which two (or more) components communicate via an interconnection link; and to the calibration needed to account for drift of conditions related to such parameters during operation of the communication channels.

2. Description of Related Art

In high-speed communication channels which are operated in a mesochronous manner, typically a reference clock provides frequency and phase information to the two components at either end of the link. A transmitter on one component and a receiver on another component each connect to the link. The transmitter and receiver operate in different clock domains, which have an arbitrary (but fixed) phase relationship to the reference clock. The phase relationship between transmitter and receiver is chosen so that the propagation delay seen by a signal wavefront passing from the transmitter to the receiver will not contribute to the timing budget when the signaling rate is determined. Instead, the signaling rate will be determined primarily by the drive window of the transmitter and the sample window of the receiver. The signaling rate will also be affected by a variety of second order effects. This system is clocked in a mesochronous fashion, with the components locked to specific phases relative to the reference clock, and with the drive-timing-point and sample-timing-point of each link fixed to the phase values that maximize the signaling rate.

These fixed phase values may be determined in a number of ways. A sideband link may accompany a data link (or links), permitting phase information to be passed between transmitter and receiver. Alternatively, an initialization process may be invoked when the system is first given power, and the proper phase values determined by passing calibration information (patterns) across the actual link. Once the drive-timing-point and sample-timing-point of each link has been fixed, the system is permitted to start normal operations.

However, during normal operation, system conditions will change. Ambient temperature, component temperature, supply voltages, and reference voltages will drift from their initial values. Clock frequencies may drift due to environmental and operational factors, or be intentionally caused to drift in spread spectrum clock systems, and the like. Typically, the frequency drift will be constrained to lie within a specified range, and many of the circuits in the components will be designed to be insensitive to the drift. Nonetheless, the drift will need to be considered when setting the upper signaling rate of a link. In general, a channel parameter may be calibrated as a function of one or more changing operating conditions or programmed settings. In many cases, drifting parameters will be plotted in the form of a two-dimensional Schmoo plot for analysis. Examples of programmed settings, which might be subject of calibration, or which might cause drift in other channel parameters, include transmitter amplitude, transmitter drive strength, transmitter common-mode offset, receiver voltage reference, receiver common-mode offset, and line termination values.

As the conditions drift or change, the optimal timing points of the transmitter and receiver will change. If the timing points remain at their original values, then margin must be added to the timing windows to ensure reliable operation. This margin will reduce the signaling rate of the link.

It is desirable to provide techniques to compensate for the condition drift, and provide improvements in system and component design to permit these techniques to be utilized.

SUMMARY OF THE INVENTION

The present invention provides a system and method for calibrating a communication channel, which allows for optimizing timing windows and accounting for drift of properties of the channel. A communication channel includes a first component having a transmitter coupled to a normal data source, and at least a second component having a receiver coupled to a normal signal destination. A communication link couples the first and second components, and other components on the link. The present invention includes a method and system that provides for execution of calibration cycles from time to time during normal operation of the communication channel. A calibration cycle includes de-coupling the normal data source from the transmitter and supplying a calibration pattern in its place. The calibration pattern is transmitted on the link using the transmitter on the first component. After transmitting the calibration pattern, the normal data source is re-coupled to the transmitter. The calibration pattern is received from the communication link using the receiver on the second component. A calibrated value of a parameter of the communication channel is determined in response to the received calibration pattern. In some embodiments of the invention, the communication channel is bidirectional, so that the first component includes both a transmitter and a receiver, and second component likewise includes both a transmitter and receiver.

The communication channel transmits data using the transmitter on the first component and receives data using the receiver on the second component with a first parameter of the communication channel, such as one of a receive and transmit timing point for the transmissions from the first to the second component, set to an operation value, and receives data using the receiver on the first component and transmits data using the transmitter on the second component with a second parameter of the communication channel, such as one of a receive and transmit timing point for the transmissions from the second to the first component, set to an operation value.

According to one embodiment of the invention, a method comprises:

-   -   storing a value of a first edge parameter and a value of a         second edge parameter, wherein an operation value of said         parameter of the communication channel is a function of the         first and second edge parameters;     -   executing a calibration cycle;     -   the calibration cycle including iteratively adjusting the value         of the first edge parameter, transmitting a calibration pattern         using the transmitter on the first component, receiving the         calibration pattern using the receiver on the second component,         and comparing the received calibration pattern with a stored         calibration pattern, to determine an updated value for the first         edge value;     -   the calibration cycle also including iteratively adjusting the         value of the second edge parameter, transmitting a calibration         pattern using the transmitter on the first component, receiving         the calibration pattern using the receiver on the second         component, and comparing the received calibration pattern with a         stored calibration pattern, to determine an updated value for         the second edge value; and     -   as a result of the calibration cycle, determining a new         operation value for the parameter based on the function of the         updated values of the first and second edge parameters.

Some embodiments of the invention comprise a calibration method comprising:

-   -   executing a calibration cycle including transmitting a         calibration pattern using the transmitter on the first component         and receiving the calibration pattern using the receiver on the         second component with the first parameter set to a calibration         value, and determining a calibrated value of the first parameter         in response to the received calibration pattern; and     -   prior to determining said calibrated value of said calibration         cycle, transmitting data using the transmitter on the second         component and receiving the data using the receiver on the first         component with the second parameter set to the operation value.

Methods according to some embodiments of the invention comprise executing calibration cycles from time to time, the calibration cycles comprising:

-   -   de-coupling the data source from the transmitter;     -   adjusting the parameter to a calibration value;     -   supplying a calibration pattern to the transmitter;     -   transmitting the calibration pattern on the communication link         using the transmitter on the first component;     -   receiving the calibration pattern on the communication link         using the receiver on the second component;     -   re-coupling the data source to the transmitter and setting the         parameter to the operation value; and     -   determining a calibrated value of the parameter of the         communication channel in response to the received calibration         pattern, wherein said re-coupling occurs prior to said         determining.

A variety of parameters of the communication channel can be calibrated according to the present invention. In some embodiments, the parameter being calibrated is a transmit timing point for the transmitter of the first component. In some embodiments, the parameter being calibrated is a receive timing point for the receiver of the second component. In yet other embodiments including bidirectional links, the parameter being calibrated is a receive timing point for the receiver of the first component. Also, embodiments of the present invention including bidirectional links provide for calibration of both receive timing points and transmit timing points for the receiver and transmitter respectively of the first component.

In some embodiments that include bidirectional links, calibration cycles are executed which include a step of storing received calibration patterns on the second component, and retransmitting such calibration patterns back to logic on the first component for use in calibrating receive or transmit timing points in the first component. In these embodiments, the second component provides storage for holding the received calibration patterns for a time period long enough to allow the first component to complete transmission of a complete calibration pattern, or at least a complete segment of a calibration pattern. The storage can be embodied by special-purpose memory coupled with the receiver on the second component, or it can be provided by management of memory space used by the normal destination on the second component. For example, the second component comprises an integrated circuit memory device in some embodiments, where the memory device includes addressable memory space. The storage provided for use by the calibration cycles is allocated from addressable memory space in the memory device in these embodiments. In yet other embodiments, where the second component includes latch type sense amplifiers associated with memory on the component, calibration patterns may be stored in the latch type sense amplifiers while decoupling the sense amplifiers from the normally addressable memory space. In yet other embodiments, in which the second component comprises an integrated circuit memory having addressable memory space within a memory array, a segment of the memory array outside of the normally addressable memory space is allocated for use by the calibration cycles.

In yet other embodiments, utilization of memory at the second component can be improved by providing cache memory or temporary memory on the first component. In such embodiments, accesses to the memory array in the second component attempted during a calibration cycle are directed to a cache memory on the first component. In other embodiments, prior to execution of the calibration cycle, a segment of the addressable memory in the second component to be used for storage of the calibration pattern is copied into temporary storage on the first component for use during the calibration cycle.

In systems and methods according to the present invention, parameters which are updated by the calibration process are applied to the communication channel so that drift in properties of the communication channel can be tracked to improve reliability and increase operating frequency of the channel. In various embodiments of the calibration process, the steps involved in calibration cycles are reordered to account for utilization patterns of the communication channel. For low latency processes, for example the step of applying the updated parameter is delayed, so that normal transmit and receive processes can be resumed as soon as the calibration pattern has been transmitted, and without waiting for computation of updated parameters. For example, the updated parameter calculated during one calibration cycle is not applied to the communication channel, until a next calibration cycle is executed. In yet another example, the calibration cycle includes a first segment in which calibration patterns are transmitted, and a second segment in which updated parameters calculated during the calibration cycle are applied, so that the time interval between completion of transmission of the calibration pattern and completion of the calculation of the updated parameters is utilized for normal transmission and receive operations.

Other aspects and advantages of the present invention can be seen on review of the drawings, the detailed description and the claims, which follow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a simplified diagram of two components interconnected by a communication channel.

FIG. 2 is a timing diagram illustrating timing parameters for a communication channel like that shown in FIG. 1.

FIG. 3 illustrates an embodiment of the present invention where both a transmitter drive point and a receiver sample point are adjustable.

FIG. 4 illustrates an embodiment of the present invention where only a receiver sample point is adjustable.

FIG. 5 illustrates an embodiment of the present invention where only a transmitter drive point is adjustable.

FIG. 6 is a flow chart illustrating calibration steps for a transmitter on a unidirectional link for a transmitter drive point.

FIG. 7 illustrates timing for iteration steps for calibrating a transmitter drive point.

FIG. 8 is a flow chart illustrating calibration steps for a receiver on a unidirectional link for a sample point.

FIG. 9 illustrates timing for iteration steps for calibrating a receiver sample point.

FIG. 10 illustrates an embodiment of the present invention where transmitter drive points and receiver sample points on components of a bidirectional link are adjustable.

FIG. 11 illustrates an embodiment of the present invention where receiver sample points on components of a bidirectional link are adjustable.

FIG. 12 illustrates an embodiment of the present invention where both components have adjustable transmitter drive points.

FIG. 13 illustrates an embodiment of the present invention where a transmitter drive point and a receiver sample point of only one component on a bidirectional link are adjustable.

FIG. 14 is a flow chart illustrating calibration steps for a transmitter drive point for a bidirectional link.

FIG. 15 is a flow chart illustrating calibration steps for a receiver sample point for a bidirectional link.

FIG. 16 and FIG. 17 illustrate time intervals for operation of components on a bidirectional link during calibration using a system like that of FIG. 13.

FIG. 18 illustrates a first embodiment of the invention including storage for calibration patterns on one component.

FIG. 19 illustrates a second embodiment of the invention including storage within a memory core used for storage of calibration patterns on one component sharing a bidirectional link.

FIG. 20 illustrates a third embodiment of the invention including storage within a memory core for storage of calibration patterns on one component sharing a bidirectional link, and a cache supporting use of a region of the memory core for this purpose.

FIG. 21 illustrates a fourth embodiment of the invention including storage within a memory core for storage of calibration patterns on one component sharing a bidirectional link, and temporary storage supporting use of the region of the memory core for this purpose.

FIG. 22 illustrates a fifth embodiment of the invention including storage within sense amplifiers, which are used for storage of calibration patterns during calibration on one component sharing a bidirectional link.

FIG. 23 is a flow chart illustrating calibration steps for a transmitter on a unidirectional link for a transmitter drive point, with re-ordered steps for improved throughput.

FIGS. 24A and 24B are flow charts illustrating calibration steps for a transmitter drive point for a bidirectional link, with re-ordered steps for improved throughput.

FIG. 25 illustrates an embodiment of the present invention where a transmitter drive point and a receiver sample point of one component on a bidirectional link are adjustable with a plurality of parameter sets, and wherein the bidirectional link is coupled to a plurality of other components corresponding to the plurality of parameter sets.

DETAILED DESCRIPTION

A detailed description of embodiments of the present invention is provided with reference to the Figures.

Transmitter and Receiver Timing Parameters

FIG. 1 shows two components 10, 11 connected with an interconnection medium, referred to as Link 12. One has a transmitter circuit 13 which drives symbols (bits) on Link 12 in response to rising-edge timing events on the internal CLKT signal 14. This series of bits forms signal DATAT. The other has a receiver circuit 15 which samples symbols (bits) on Link 12 in response to rising-edge timing events on the internal CLKR signal 16. This series of bits forms signal DATAR. FIG. 2 illustrates the timing parameters, including the transmit clock CLKT signal 14 on trace 20, the transmitter signal DATAT on trace 21, the receive clock CLKR signal 16 on trace 22, and the receiver signal DATAR on trace 23. The transmitter eye 24 and the receiver eye 25 are also illustrated. The transmitter eye 24 is a window during which the signal DATAT is transmitted on the link. The receiver eye is a sampling window defined by the is setup time and t_(H) hold time which surround the CLKR rising edge 35, 36 and define the region in which the value of DATAR must be stable for reliable sampling. Since the valid window of the DATAT signal is larger than this setup/hold sampling window labeled receiver eye 25, the receiver has timing margin in both directions.

The DATAT and DATAR signals are related; DATAR is an attenuated, time-delayed copy of DATAT. The attenuation and time-delay occur as the signal wavefronts propagate along the interconnection medium of Link 12.

The transmitter circuit 13 will begin driving a bit (labeled “a”) no later than a time t_(Q,MAX) after a rising edge 30 of CLKT, and will continue to drive it during transmitter eye 24 until at least a time t_(V,MIN) after the next rising edge 31. t_(Q,MAX) and t_(V,MIN) are the primary timing parameters of the transmitter circuit 13. These two values are specified across the full range of operating conditions and processing conditions of the communication channel. As a result, t_(Q,MAX) will be larger than t_(V,MIN), and the difference will represent the dead time or dead band 32 of the transmitter circuit 13. The transmitter dead band 32 (t_(DEAD,T)) is the portion of the bit timing window (also called bit time or bit window) that is consumed by the transmitter circuit 13: t _(DEAD,T) =t _(Q,MAX) −t _(V,MIN)

The receiver circuit 15 will sample a bit (labeled “a”) during the receiver eye 25 no earlier than a time t_(S,MIN) before a rising edge 35 of CLKR, and no later than a time t_(H,MIN) after the rising edge 35. t_(S,MIN) and t_(H,MIN) are the primary timing parameters of the receiver circuit. These two values are specified across the full range of operating conditions and processing conditions of the circuit. The sum of t_(S,MIN) and t_(H,MIN) will represent the dead time or dead band 37, 38 of the receiver. The receiver dead band 37, 38 (t_(DEAD,R)) is the portion of the bit timing window (also called bit time or bit window) that is consumed by the receiver circuit: t _(DEAD,R) =t _(S,MIN) +t _(H,MIN)

In this example, the bit timing window (receiver eye 25) is one t_(CYCLE) minus the t_(DEAD,T) and t_(DEAD,R) values, each of which is about ⅓ of one t_(CYCLE) in this example.

Unidirectional Link Alternatives

FIG. 3 shows two components 100 (transmit component) and 101 (receive component) connected with an interconnection medium referred to as Link 102. The link is assumed to carry signals in one direction only (unidirectional), so one component 100 has a transmitter circuit 103 coupled to a data source 110 labeled “normal path,” and one component 101 has a receiver circuit 104 coupled to a destination 111 labeled “normal path”. There are additional circuits present to permit periodic adjustment of the drive point and sample point in between periods of normal system operation. These adjustments compensate for changes in the system operating conditions.

The transmitter component includes a block 105 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of transmit calibration patterns. A multiplexer block 106 labeled “mux,” implemented for example using a logical layer (by which the normal data path may act as a source of calibration patterns and, for example, a virtual switch is implemented by time multiplexing normal data and calibration patterns) or physical layer switch, enables the transmit calibration pattern set to be driven onto the link by the transmitter circuit. The transmitter drive point can be adjusted by the block 107 labeled “adjust”. A sideband communication channel 113 is shown coupled between the component 101 and the component 100, by which the results of analysis of received calibration patterns at the component 101 are supplied to the adjust block 107 of the component 100.

The receiver component 101 includes a block 108 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of expected patterns. A block 109 labeled “compare” enables the received pattern set to be compared to the expected pattern set, and causes an adjustment to be made to either the transmitter or receiver. The receiver sample point can be adjusted by the block 112 labeled “adjust”.

FIG. 4 shows two components 100, 101 connected with a unidirectional link 102, in which components of FIG. 3 are given like reference numerals. In the embodiment of FIG. 4, only the receiver sample point can be adjusted; the transmitter drive point remains fixed during system operation. Thus, there is no adjust block 107 in the component 100, nor is there a need for sideband communication channel 113 of FIG. 4.

FIG. 5 shows two components 100, 101 connected with a unidirectional link 102, in which components of FIG. 3 are given like reference numerals. In the embodiment of FIG. 5, only the transmitter drive point can be adjusted; the receiver sample point remains fixed during system operation. Thus, there is no adjust block 112 in the component 101 of FIG. 5.

In general, periodic timing calibration can be performed on all three examples, since timing variations due to condition drift can be compensated at either the transmitter end or the receiver end. In practice, it is cheaper to put the adjustment circuitry at only one end of the link, and not at both ends, so systems of FIG. 4 or 5 would have an advantage. Also, it should be noted that system of FIG. 4 does not need to communicate information from the “compare” block 109 in the receiver component 101 back to the transmitter component 100, and thus might have implementation benefits over system of FIG. 5.

Calibration Steps for Transmitter for Unidirectional Link

FIG. 6 shows the example from FIG. 5, and also includes the steps needed to perform a timing calibration update.

(Step 601) Suspend normal transmit and receive operations, by completing transactions in progress and preventing new ones from beginning, or by interrupting transactions that are in progress.

(Step 602) Change the drive point of the transmit component from the “TX” operation value (used for normal operations) to either the “TXA” or “TXB” edge value (used for calibration operations) in the “adjust” block. The “TX” operation value may be a simple average of “TXA” and “TXB,” i.e. a center value, or it may be another function of “TXA” and “TXB,” such as a weighted average. It may be necessary to impose a settling delay at this step to allow the new drive point to become stable.

(Step 603) Change “mux” block of the transmit component so that the “pattern” block input is enabled.

(Step 604) A pattern set is created in the “pattern” block of the transmit component and is transmitted onto the “link” using the TXA or TXB drive point.

(Step 605) The pattern set is received in the receive component. Note that the sample point of the receiver is fixed relative to the reference clock of the system.

(Step 606) The received pattern set is compared in the “compare” block to the expected pattern set produced by the “pattern” block in the receive component. The two pattern sets will either match or not match. As a result of this comparison (and possibly other previous comparisons) a pass or fail determination will be made.

(Step 607) Adjust either the “TXA” or “TXB” edge value in the transmit component as a result of the pass or fail determination. The “TX” operation value in the transmit component is also adjusted. This adjustment may only be made after a calibration sequence including transmission of two or more of calibration patterns has been executed, in order to ensure some level of repeatability.

(Step 608) Change the drive point of the transmitter from the “TXA” or “TXB” edge value (used for calibration operations) to “TX” operation value (used for normal operations) in the “adjust” block of the transmit component. It may be necessary to impose a settling delay at this step to allow the new drive point to become stable.

(Step 609) Change “mux” block of the transmit component so that the “normal path” input is enabled.

(Step 610) Resume normal transmit and receive operations.

Timing for Iteration Step for Transmit

FIG. 7 includes the timing waveforms used by the calibration steps of FIG. 6 for a system like that of FIG. 5. These timing waveforms are similar to those from FIG. 2, except that the drive point is adjusted to straddle the sampling window of the receiver in order to track the edges of the valid window of the transmitter.

The “adjust” block in the transmit component maintains three values in storage: TXA, TX, and TXB. The TX value is the operation value used for normal operation. The TXA and TXB are the “edge” values, which track the left and right extremes of the bit window of the transmitter. Typically, the TX value is derived from the average of the TXA and TXB values, but other relationships are possible. The TXA and TXB values are maintained by the calibration operations, which from time to time, and periodically in some embodiments, interrupt normal operations.

In FIG. 7, the position of the rising edge of CLKT has an offset of t_(PHASET) relative to a fixed reference (typically a reference clock that is distributed to all components).

When the TX value is selected (t_(PHASET(TX)) in the middle trace 701 showing CLKT timing waveform) for operation, the rising edge 702 of CLKT causes the DATAT window 703 containing the value “a” to be aligned so that the DATAR signal (not shown but conceptually overlapping with the DATAT signal) at the receiving component is aligned with the receiver clock, successfully received, and ideally centered on the receiver eye.

When the TXA value is selected (t_(PHASET(TXA)) in the top trace 705 showing CLKT timing waveform), the rising edge of CLKT is set to a time that causes the right edges of the DATAT window 706 (containing “a”) and the receiver setup/hold window 710 (shaded) to coincide. The t_(S) setup time and t_(H) hold time surround the CLKR rising edge, together define the setup/hold window 710 (not to be confused with the receiver eye of FIG. 2) in which the value of DATAR must be stable for reliable sampling around a given CLKR rising edge 704. Since the DATAT window, and the resulting DATAR window, are larger than this setup/hold window 710, the transmitter has timing margin. However, in the case shown on trace 705 with the transmit clock rising edge at offset t_(PHASET(TXA)), all the timing margin is on the left side of the transmitter eye for the setup/hold window 710, adding delay after the t_(Q) timing parameter. There is essentially no margin for the t_(V) timing parameter in the trace 705, so that the offset defines the left edge of the calibration window.

The calibration process for TXA will compare the received pattern set to the expected pattern set, and determine if they match. If they match (pass) then the TXA value will be decremented (the T_(TPHASET(TXA)) offset becomes smaller shifting the transmit window 706 to the left in FIG. 7) or otherwise adjusted, so there is less margin for the t_(V) timing parameter relative to the receiver window 710. If they do not match (fail) then the TXA value will be incremented (the T_(PHASET(TXA)) offset becomes larger shifting the transmit window 706 to the right in FIG. 7, or otherwise adjusted, so there is more margin for the t_(V) timing parameter.

As mentioned earlier, the results of a sequence including transmission of two or more calibration patterns may be accumulated before the TXA value is adjusted. This would improve the repeatability of the calibration process. For example, the calibration pattern could be repeated “N” times with the number of passes accumulated in a storage element. If all N passes match, then the TXA value is decremented. If any of the N passes does not match, then the TXA value is determined to have reached the edge of the window and is incremented. In another alternative, after the Nth pattern, the TXA value could be incremented if there are fewer than N/2 (or some other threshold number) passes, and decremented if there are N/2 or more passes.

When TXA is updated, the TX value will also be updated. In this example, the TX value will updated by half the amount used to update TXA, since TX is the average of the TXA and TXB values. If TX has a different relationship to TXA and TXB, the TX update value will be different. Note that in some embodiments, the TX value will need slightly greater precision than the TXA and TXB values to prevent round-off error. In alternate embodiments, the TX value can be updated after pass/fail results of TXA and TXB values have been determined. In some cases, these results may cancel and produce no change to the optimal TX value. In other cases these results may be accumulated and the accumulated results used to determine an appropriate adjustment of the TX setting. According to this embodiment, greater precision of the TX setting relative to the TXA and TXB settings may not be required.

When the TXB value is selected (t_(PHASER(TXB)) in the bottom trace 707 showing a CLKT timing waveform) for calibration, the rising edge of CLKT is set to a time that causes the left edge of the transmitter valid window 708 (containing “a”) and the receiver setup/hold window 710 (shaded) to coincide. In this case with the transmit clock rising edge at t_(PHASER(TXB)), all the timing margin is on the right side of the transmit window 708, providing more room than required by the t_(V) timing parameter. This means that there will be essentially no margin for the t_(Q) timing parameter on the left side of the window 708, defining the right edge of the calibration window.

The calibration process will compare the received pattern set to the expected pattern set, and determine if they match. If they match (pass) then the TXB value will be incremented (the offset becomes larger) or otherwise adjusted, so there is less margin for the t_(Q) timing parameter. If they do not match (fail) then the TXB value will be decremented (the offset becomes smaller) or otherwise adjusted, so there is more margin for the t_(Q) timing parameter.

As mentioned earlier, the results of transmission of two or more calibration patterns may be accumulated before the TXB value is adjusted. For example, transmission of the patterns could be repeated “N” times with the number of passes accumulated in a storage element. After the Nth sequence the TXB value could be decremented if there are fewer than N/2 passes and incremented if there are N/2 or more passes. This would improve the repeatability of the calibration process.

When TXB is updated, the TX value will also be updated. In this example, the TX value will updated by half the amount used to update TXB, since TX is the average of the TXA and TXB values. If TX has a different relationship to TXA and TXB, the TX update value will be different. Note that the TX value will need slightly greater precision than the TXA and TXB values if it is desired to prevent round-off error.

Calibration Steps for Receiver for Unidirectional Link

FIG. 8 shows the example from FIG. 4, and also includes the steps needed to perform a timing calibration update. Note that only steps (Block 802), (Block 807), and (Block 808) are different relative to the steps in FIG. 6.

(Step 801) Suspend normal transmit and receive operations, by completing transactions in progress and preventing new ones from beginning, or by interrupting transactions that are in progress.

(Step 802) Change the sample point of the receive component from the “RX” operation value (used for normal operations) to either the “RXA” or “RXB” edge value (used for calibration operations) in the “adjust” block. The “RX” operation value may be a simple average of “RXA” and “RXB,” i.e. a center value, or it may be another function of “RXA” and “RXB,” such as a weighted average. It may be necessary to impose a settling delay at this step to allow the new sample point to become stable.

(Step 803) Change “mux” block of the transmit component so that the “pattern” block input is enabled.

(Step 804) A pattern set is created in the “pattern” block of the transmit component and is transmitted onto the “link” using the TXA or TXB drive point.

(Step 805) The pattern set is received in the receive component. Note that the transmit point of the transmitter is fixed relative to the reference clock of the system.

(Step 806) The received pattern set is compared in the “compare” block to the expected pattern set produced by the “pattern” block in the receive component. The two pattern sets will either match or not match. As a result of this comparison (and possibly other previous comparisons) a pass or fail determination will be made.

(Step 807) Adjust either the “RXA” or “RXB” edge value in the receive component as a result of the pass or fail determination. The “RX” operation value in the transmit component is also adjusted. This adjustment may only be made after two or more of these calibration sequences have been executed, in order to ensure some level of repeatability.

(Step 808) Change the sample point of the receiver from the “RXA” or “RXB” edge value (used for calibration operations) to “RX” operation value (used for normal operations) in the “adjust” block of the receive component. It may be necessary to impose a settling delay at this step to allow the new sample point to become stable.

(Step 809) Change “mux” block of the transmit component so that the “normal path” input is enabled.

(Step 810) Resume normal transmit and receive operations.

Timing for Iteration Step for Receive

FIG. 9 shows includes the timing waveforms used by the receiver calibration steps of FIG. 8 for a system configured for example as shown in FIG. 4. These timing waveforms are similar to those from FIG. 2, except that the sampling point is adjusted within the bit window in order to track the edges of the window.

The “adjust” block in the receive component maintains three values in storage: RXA, RX, and RXB. The RX value is the operation value used for normal operation. The RXA and RXB are the “edge” values, which track the left and right extremes of the bit window. Typically, the RX value is derived from the average of the RXA and RXB values, but other relationships are possible. The RXA and RXB values are maintained by the calibration operations, which periodically or otherwise from time to time interrupt normal operations.

In the timing diagrams, the position of the rising edge of CLKR has an offset of t_(PHASER) relative to a fixed reference (not shown, typically a reference clock that is distributed to all components). This offset is determined by the RXA, RX, and RXB values that are stored.

When the RX value is selected (t_(PHASER(RX)) in the middle trace 901 showing a CLKR timing waveform) for use in receiving data, the rising edge 902 of CLKR is approximately centered in the receiver eye of the DATAR signal containing the value “a”. The DATAR signal is the DATAT signal transmitted at the transmitter after propagation across the link, and can be conceptually considered to be the same width as DATAT as shown in FIG. 9. The receiver eye is shown in FIG. 2. The t_(S) setup time is the minimum time before the clock CLKR rising edge which must be within the DATAR window 903, and the t_(H) hold time is the minimum time after the clock CLKR rising edge that must be within the DATAR window 903, together defining the setup/hold window 904 (not to be confused with the receiver eye of FIG. 2) in which the value of DATAR must be stable for reliable sampling around a given CLKR rising edge. Since the valid window 904 of the DATAR signal is larger than this setup/hold window 904, the receiver has timing margin in both directions.

When the RXA value is selected (t_(PHASER(RXA)) in the top trace 905 showing a CLKR timing waveform), the rising edge of CLKR is approximately a time t_(S) later than the left edge (the earliest time) of the DATAR window 903 containing the value “a”. In this case, the CLKR rising edge is on the left edge of the receiver eye, and all the timing margin is on the right side of the setup/hold window 904, providing more room than is required by the t_(H) timing parameter. This means that there will be essentially no margin for the t_(S) timing parameter, defining the left edge of the calibration window.

The calibration process will compare the received pattern set to the expected pattern set, and determine if they match. If they match (pass) then the RXA value will be decremented (the offset becomes smaller) or otherwise adjusted, so there is less margin for the t_(S) timing parameter. If they do not match (fail) then the RXA value will be incremented (the offset becomes larger) or otherwise adjusted, so there is more margin for the t_(S) timing parameter.

As mentioned earlier, the results of transmission and reception of two or more calibration patterns may be accumulated before the RXA value is adjusted. For example, the patterns could be repeated “N” times with the number of passes accumulated in a storage element. After the Nth sequence the RXA value could be incremented if there are fewer than N/2 passes and decremented if there are N/2 or more passes. This would improve the repeatability of the calibration process.

When RXA is updated, the RX value will also be updated. In this example, the RX value will updated by half the amount used to update RXA, since RX is the average of the RXA and RXB values. If RX has a different relationship to RXA and RXB, the RX update value will be different. Note that in some embodiments, the RX value will need slightly greater precision than the RXA and RXB values to prevent round-off error. In alternate embodiments, the RX value can be updated after pass/fail results of RXA and RXB values have been determined. In some cases, these results may cancel and produce no change to the optimal RX value. In other cases these results may be accumulated and the accumulated results used to determine an appropriate adjustment of the RX setting. According to this embodiment, greater precision of the RX setting relative to the RXA and RXB settings may not be required.

When the RXB value is selected (t_(PHASER(RXB)) in the bottom trace 906 showing a CLKR timing waveform), the rising edge of CLKR is approximately a time t_(H) earlier than the right edge (the latest time) of the DATAR window 903 containing the value “a”. In this case, the CLKR rising edge is on the right edge of the receiver eye, and all the timing margin is on the left side of the window 904, providing more room that required by the t_(S) timing parameter. This means that there will be essentially no margin for the t_(H) timing parameter, defining the right edge of the calibration window.

The calibration process will compare the received pattern set to the expected pattern set, and determine if they match. If they match (pass) then the RXB value will be incremented (the offset becomes larger) or otherwise adjusted, so there is less margin for the tH timing parameter. If they do not match (fail) then the RXB value will be decremented (the offset becomes smaller) or otherwise adjusted, so there is more margin for the t_(H) timing parameter.

As mentioned earlier, the results of transmission and reception of two or more calibration patterns may be accumulated before the RXB value is adjusted. For example, the sequence could be repeated “N” times with the number of passes accumulated in a storage element. After the Nth sequence the RXB value could be decremented if there are fewer than N/2 passes and incremented if there are N/2 or more passes. This would improve the repeatability of the calibration process.

When RXB is updated, the RX value will also be updated. In this example, the RX value will updated by half the amount used to update RXB, since RX is the average of the RXA and RXB values. If RX has a different relationship to RXA and RXB, the RX update value will be different. Note that the RX value will need slightly greater precision than the RXA and RXB values if it is desired to prevent round-off error.

Bidirectional Link Alternatives

FIG. 10 shows an example of a bidirectional link. In this case, component A (1000) and component B (1001) each contain a transmitter and receiver connected to the link, so that information may be sent either from A to B or from B to A. The elements of the unidirectional example in FIG. 3 is replicated (two copies) to give the bidirectional example in FIG. 10. FIG. 10 shows two bidirectional components 1000, 1001 connected with an interconnection medium referred to as Link 1002. Normal path 1010 acts as a source of data signals for normal operation of component 1000 during transmit operations. Normal path 1031 acts as a destination of data signals for component 1000, during normal receive operations. Likewise, normal path 1030 acts as a source of data signals for normal operation of component 1001 during transmit operations. Normal path 1011 acts as a destination of data signals for component 1001, during normal receive operations.

The first bidirectional component includes a block 1005 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of transmit calibration patterns. A multiplexer block 1006 labeled “mux,” implemented for example using a logical layer or physical layer switch, enables the transmit calibration pattern set to be driven onto the link by the transmitter circuit 1003. The transmitter drive point can be adjusted by the block 1007 labeled “adjust”. A sideband communication channel 1013 is shown coupled between the component 1001 and the component 1000, by which the results of analysis of received calibration patterns at the component 1001 are supplied to the adjust block 1007 of the component 1000. Component 1000 also has support for calibrating receiver 1024, including a block 1028 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of expected patterns for comparison with received patterns. A block 1029 labeled “compare” enables the received pattern set to be compared to the expected pattern set, and causes an adjustment to be made to either the transmitter or receiver. The receiver sample point can be adjusted by the block 1032 labeled “adjust”.

The second bidirectional component 1001 includes complementary elements supporting transmitter 1023 and receiver 1004. For the receiver operations, a block 1008 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of expected patterns. A block 1009 labeled “compare” enables the received pattern set to be compared to the expected pattern set, and causes an adjustment to be made to either the transmitter or receiver. The receiver sample point can be adjusted by the block 1012 labeled “adjust”. The second bidirectional component 1001 supports transmission operations, with elements including a block 1025 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of transmit calibration patterns. A multiplexer block 1026 labeled “mux,” implemented for example using a logical layer or physical layer switch, enables the transmit calibration pattern set to be driven onto the link by the transmitter circuit 1023. The transmitter drive point can be adjusted by the block 1027 labeled “adjust”. A sideband communication channel 1033 is shown coupled between the component 1000 and the component 1001, by which the results of analysis of received calibration patterns at the component 1000 are supplied to the adjust block 1027 of the component 1001.

The example of FIG. 10 allows both receive sample points and both transmit drive points to be adjusted. However, the benefit of adjustable timing can be realized if there is only one adjustable element in each direction.

The example of FIG. 11 (using the same reference numerals as FIG. 10) shows an example in which only the receiver sample points are adjustable. Thus, elements 1007 and 1027 of FIG. 10 are not included in this embodiment. This is equivalent to two copies of the elements of example in FIG. 4.

The example of FIG. 12 (using the same reference numerals as FIG. 10) shows an example in which only the transmitter drive points are adjustable. Thus, elements 1012 and 1032 of FIG. 10 are not included in this embodiment. This is equivalent to two copies of the elements of example in FIG. 5.

The example of FIG. 13 (using the same reference numerals as FIG. 10) shows an example in which the receiver sample point and transmitter drive point of the first bidirectional component 1000 are adjustable. Thus, elements 1012, 1008, 1009, 1027, 1026, 1025 are not included in this embodiment. A storage block 1050 is added between the receiver and a “mux” block 1051. The “mux” block 1051 is used to select between a normal source of signals 1030 and the storage block 1050. Also, the compare block 1052 is used for analysis of both transmit and receive calibration operations, and is coupled to both the adjust block 1007 for the transmitter, and adjust block 1032 for the receiver. This alternative is important because all the adjustment information can be kept within one component, eliminating the need for sideband signals for the calibration process. If component 1001 were particularly cost sensitive, this could also be a benefit, since only one of the components must bear the cost of the adjustment circuitry.

Calibration Steps for Transmitter for Bidirectional Link

The calibration steps for bidirectional examples in FIGS. 10, 11 and 12 can be essentially identical to the calibration steps already discussed for unidirectional examples in FIGS. 4 and 5. However, the asymmetry in bidirectional example of FIG. 13 will introduce some additional calibration steps, and will receive further discussion.

FIG. 14 shows the example from FIG. 13, and also includes the steps needed to perform a timing calibration update.

(Step 1401) Suspend normal transmit and receive operations, by completing transactions in progress and preventing new ones from beginning, or by interrupting transactions that are in progress.

(Step 1402) Change the drive point of the transmit component (A) from the “TX” operation value (used for normal operations) to either the “TXA” or “TXB” edge value (used for calibration operations) in the “adjust” block. It may be necessary to impose a settling delay at this step to allow the new drive point to become stable.

(Step 1403) Change “mux” block of the transmit component (A) so that the “pattern” block input is enabled.

(Step 1404) A pattern set is created in the “pattern” block of the transmit component (A) and is transmitted onto the “link” using the TXA or TXB drive point.

(Step 1405) The pattern set is received in the receive component (B). Note that the sample point of the receiver is fixed relative to the reference clock of the system. The received pattern set is held in the “storage” block in component B.

(Step 1406) The “mux” block input connected to the “storage” block in component B is enabled. The pattern set is re-transmitted onto the link by component B.

(Step 1407) The pattern set is received by component A from the link.

(Step 1408) The received pattern set is compared in the “compare” block to the expected pattern set produced by the “pattern” block in the receive component (A). The two pattern sets will either match or not match. As a result of this comparison (and possibly other previous comparisons) a pass or fail determination will be made.

(Step 1409) Adjust either the “TXA” or “TXB” edge value in the transmit component (A) as a result of the pass or fail determination. The “TX” operation value in the transmit component (A) is also adjusted. This adjustment may only be made after two or more of these calibration sequences have been executed, in order to ensure some level of repeatability.

(Step 1410) Change the drive point of the transmitter from the “TXA” or “TXB” edge value (used for calibration operations) to “TX” operation value (used for normal operations) in the “adjust” block of the transmit component (A). It may be necessary to impose a settling delay at this step to allow the new drive point to become stable.

(Step 1411) Change “mux” block of the transmit component (A) so that the “normal path” input is enabled.

(Step 1412) Resume normal transmit and receive operations.

Calibration Steps for Receiver for Bidirectional Link

The calibration steps for bidirectional examples of FIGS. 10, 11, and 12 can be essentially identical to the calibration steps already discussed for unidirectional examples of FIGS. 4 and 5. However, the asymmetry in bidirectional example of FIG. 13 will introduce some additional calibration steps, and will receive further discussion.

FIG. 15 shows the example from FIG. 13, and also includes the steps needed to perform a timing calibration update.

(Step 1501) Suspend normal transmit and receive operations, by completing transactions in progress and preventing new ones from beginning, or by interrupting transactions that are in progress.

(Step 1502) Change the sample point of the receive component (A) from the “RX” operation value (used for normal operations) to either the “RXA” or “RXB” edge value (used for calibration operations) in the “adjust” block. It may be necessary to impose a settling delay at this step to allow the new drive point to become stable.

(Step 1503) Change “mux” block of the transmit component (A) so that the “pattern” block input is enabled.

(Step 1504) A pattern set is created in the “pattern” block of the transmit component (A) and is transmitted onto the “link”. The normal transmit drive point is used.

(Step 1505) The pattern set is received in the receive component (B). Note that the sample point of the receiver is fixed relative to the reference clock of the system and is not adjustable. The received pattern set is held in the “storage” block in component B.

(Step 1506) The “mux” block input connected to the “storage” block in component B is enabled. The pattern set is re-transmitted onto the link by component B.

(Step 1507) The pattern set is received by component A from the link using either the RXA or RXB value to determine the receiver sample point.

(Step 1508) The received pattern set is compared in the “compare” block to the expected pattern set produced by the “pattern” block in the receive component (A). The two pattern sets will either match or not match. As a result of this comparison (and possibly other previous comparisons) a pass or fail determination will be made.

(Step 1509) Adjust either the “RXA” or “RXB” edge value in the receive component (A) as a result of the pass or fail determination. The “RX” operation value in the receive component (A) is also adjusted. This adjustment may only be made after two or more of these calibration sequences have been executed, in order to ensure some level of repeatability.

(Step 1510) Change the sample point of the receiver from the “RXA” or “RXB” edge value (used for calibration operations) to “RX” operation value (used for normal operations) in the “adjust” block of the receive component (A). It may be necessary to impose a settling delay at this step to allow the new sample point to become stable.

(Step 1511) Change “mux” block of the transmit component (A) so that the “normal path” input is enabled.

(Step 1512) Resume normal transmit and receive operations.

Bidirectional Link—Storage Options

The bidirectional example in FIG. 13 utilizes a storage block 1050 as part of the calibration process. There are a number of alternative options for implementing this storage, each option with its own costs and benefits.

FIG. 13 shows an option in which the storage block is implemented as part of the interface containing the transmit and receive circuits. This has the benefit that the circuitry used for normal operations (the “normal path”) is not significantly impacted. The cost of this option is that the storage block will increase the size of the interface, and will thus increase the manufacturing cost of the component 1001.

FIG. 16 and FIG. 17 show why a storage block is needed for the implementations of example of FIG. 13. The storage allows the received pattern set in component 1001 to be held (and delayed) prior to being re-transmitted. FIG. 16 shows a gap 1600 between the interval 1601 in which the pattern set is being transmitted by A (and received by B) and the interval 1602 in which the pattern set being transmitted by B (and received by A). If no storage was present, there would be a relatively small delay between the start of each these two intervals resulting in an overlap of the intervals, as shown in FIG. 17. In general, components on a bidirectional link are not allowed to transmit simultaneously, so some storage will be required with the configuration of FIG. 13 to prevent this.

It is possible to design the transmitter circuits and the link so that transmitters on both ends are enabled simultaneously. This is called simultaneous bidirectional signaling. In such a communication system, the storage block of configuration of FIG. 13 could be left out of component 1001. Typically, simultaneous bidirectional signaling requires additional signal levels to be supported. For example, if each of two transmitters can be signaling a bit, there are four possible combinations of two transmitters simultaneously driving one bit each. The four combinations are {0/0, 0/1, 1/0, 1/1}. Typically the 0/1 and 1/0 combinations will produce the same composite signal on the link. This requires that the transmitter circuits be additive, so that three signal levels are produced {0, 1, 2}. The receiver circuits will need to discriminate between these three signal levels. A final requirement of simultaneous bidirectional signaling is that a component must subtract the value it is currently transmitting from the composite signal that it is currently receiving in order to detect the actual signal from the other component. When these requirements are in place, the storage block requirement can be dropped. This is one of the benefits of this approach. The cost of this approach is the extra design complexity and reduced voltage margins of simultaneous bidirectional signaling.

FIG. 18 shows option B in which the storage block is implemented from the storage elements 1801, 1802 that are normally present in the transmit and receive circuits. These storage elements are typically present for pipelining (delaying) the information flowing on the normal paths. Storage elements may also be present to perform serialization and deserialization. This would be required if the internal and external signal groups have different widths. For example, the external link could consist of a single differential wire pair carrying information at the rate or 3200 Mb/s, and could connect to a set of eight single-ended internal wires carrying information at the rate of 400 Mb/s. The information flow is balanced (no information is lost), but storage is still required to perform serial-to-parallel or parallel-to-serial conversion between the two sets of signals. This storage will create delay, which can be used to offset the two pattern sets in the option of FIG. 18. The benefit of this approach is that no extra storage must be added to component 1001. The cost is that the wiring necessary to connect the receiver to a “mux” block in the transmitter may be significant. Another cost is that the amount of storage naturally present in the receiver and transmitter may be relatively small, limiting the length of the pattern set which can be received and retransmitted with this approach.

FIG. 19 shows an option in which the storage block is implemented from the storage cells that are normally present in a memory core 1900. In this option, component 1001 is assumed to be a memory component. In this case, the storage area 1901, labeled “region”, is reserved for receiving the pattern set from component 1000, and for retransmitting the pattern set back to component 1000. This storage area may only be used by the calibration process, and should not be used by any normal application process. If this storage area were used by an application process, it is possible that application information could be overwritten by the pattern set information and thereby lost. The benefit of this approach is that no additional storage needs to be added to component 1001 (and no special path from receiver to transmitter). The cost of this approach is that a hole is created in the address space of the memory component. Since most memory components contain a power-of-two number of storage cells, this may create a problem with some application processes, particularly if two or more memory components must create a contiguous memory address space (i.e. with no holes).

FIG. 20 shows an option in which the storage block is again implemented from the storage cells that are normally present in a memory core 1900. In this option, component B is assumed to be a memory component. In this case, the storage area 1901 labeled “region” is reserved for receiving the pattern set from component 1000, and for retransmitting the pattern set back to component 1000. This storage area may only be used by the calibration process, and should not be used by any normal application process. Unlike the option in FIG. 19, however, component 1000 adds a storage block 2001, labeled “cache”, which emulates the storage capability of the storage area 1901 “region”. When a write is performed to the “region” of storage area 1901, it is intercepted and redirected to the “cache” in storage 2001. Likewise, when a read is performed to the “region” of storage area 1901, the read is intercepted and redirected, returning read data from “cache” via mux 2002. In this way, the application processes see no hole in the memory address space. The benefit of this option is that no additional storage needs to be added to component 1001 (and no special path from receiver to transmitter). The cost of this approach is that a storage block 2001 “cache,” with address comparison logic to determine when the application is attempting to access the region 1901, must be added to component 1000, as well as the control logic and “mux” block 2002 needed to intercept read and write commands for component 1001.

FIG. 21 shows an option in which the storage block is again implemented from the storage cells that are normally present in a memory core 1900. In this option, component 1001 is assumed to be a memory component. In this case, the storage area 1901 labeled “region” is used for receiving the pattern set from component 1000, and for retransmitting the pattern set back to component 1000. This storage area 1901 may be used by both the calibration process and by the application processes, however. In order to ensure that the application processes are not affected by the periodic calibration process, a temporary storage block 2101, labeled “temp”, is provided in component 1000, along with a “mux” block 2102 for accessing it. When a calibration process starts, the contents of “region” are read and loaded into “temp” storage block 2101. The calibration process steps may now be carried out using the storage area 1901. When the calibration sequence has completed, the contents of “temp” storage block 2101 are accessed and written back to the “region” of storage area 1901, and the application process allowed to restart. Again, the application processes see no hole in the memory address space. The benefit of this option is that no additional storage needs to be added to component 1001 (and no special path from receiver to transmitter). The cost of this approach is that a storage block 2101 and the “mux” block 2102 must be added to component 1000. The calibration process becomes longer, since a read operation must be added to the beginning, and a write operation must be added to the end, supporting the use of the “temp” storage block 2101.

FIG. 22 shows an option in which the storage block is implemented from the latching sense amplifier circuit 2201 that is present in a memory component 1001. Latching sense amplifier circuit 2201 includes latches or other storage resources associated with sense amplifiers. Most memory components use such a latching sense amplifier circuit 2201 to access and hold a row 2202 of storage cells from the memory core 1900. Read operations are then directed to the sense amplifier which temporarily holds the contents of the row of storage cells. Write operations are directed to both the sense amplifier and to the row of storage cells so that the information held by these two storage structures is consistent. When another row of storage cells is to be accessed, the sense amplifier is precharged and reloaded with this different row.

When component 1001 is a memory component with such a latching sense amplifier circuit 2201, it is possible to modify its operation to permit a special mode of access for calibration. In this special mode, the sense amplifier may be written by the receiver circuit 1004 and may read to the transmitter circuit 1023 without first being loaded from a row 2202 of storage cells in the memory core 1900. This permits the storage resource of the sense amplifier circuits 2201 to be used to store received calibration patterns, or portions of received calibration patterns, in region 2203 (which may include less than an entire row in some embodiments) for calibration without affecting the contents of the memory core, which would affect the interrupted application process. This second access mode would require a gating circuit 2204 between the memory core and the sense amplifier, which could be disabled during the calibration process. There is typically such a gating circuit 2204 in most memory components.

A benefit of this option is that no additional storage needs to be added to component 1001 (and no special path from receiver to transmitter). The cost of this approach is that a modification must be made to critical circuits in the core of a memory component.

Reordering of Calibration Steps to Improve Throughput

The individual steps that are shown in the calibration processes described above do not necessarily have to be done in the order shown. In fact, if some reordering is done, the overhead of the calibration process can be reduced, improving the effective signaling bandwidth of the system and reducing the worst case delay seen by latency—sensitive operations.

For example, in the case of the calibration process for the transmitter shown in FIG. 6, it is not necessary to perform the evaluation steps and the update steps (compare 606 and adjust 607) in sequence as shown. Instead, the transmitter calibration process may be performed in the following manner:

(Step 2301) Suspend normal transmit and receive operations, by completing transactions in progress and preventing new ones from beginning, or by interrupting transactions that are in progress.

(Step 2302) Control the “adjust” logic so the transmitter uses a calibrate (TXA/TXB) drive-timing-point according to the stored results of the previous comparison.

(Step 2303) Control the “adjust” logic so that the pattern block is coupled to the transmitter.

(Step 2304) A pattern sequence is read or created from the pattern block and is transmitted onto the interconnect using the selected calibrate drive-timing-point.

(Step 2305) The pattern sequence is received using the normal (RX) sample-timing-point.

(Step 2306) Control the “adjust” logic so the transmitter uses a normal (TX) drive-timing-point.

(Step 2307) Control the “adjust” logic so that the “normal path” to the transmitter is enabled.

(Step 2308) Resume normal transmit and receive operations.

(Step 2309) The received pattern sequence is compared to the expected pattern sequence from the “pattern” block.

(Step 2310) The calibrate drive-timing-point (TXA/TXB, TX) is adjusted according to the results of the comparison.

In the modified sequence, normal transmit and receive operations may be restarted earlier. This is possible because the comparison results are saved and used to adjust the timing point during the next calibration process.

A more significant saving in overhead is possible in the system of FIG. 13, by changing the order of steps in the process of FIG. 14, for example. It is possible to separate the evaluation and update steps as previously described. However, it is also possible to perform receive operations with the first component while its transmitter is changing the drive-timing-point between the normal and calibrate values. The periodic calibration process could become:

(Step 2401 a) Suspend normal transmit operations, by completing transactions in progress and preventing new ones from beginning, or by interrupting transactions that are in progress

(Step 2402 a) Control the “adjust” logic so the transmitter uses a calibrate (TXA/TXB) drive-timing-point according to the stored results of the previous comparison.

(Step 2403 a) Control the “adjust” logic that the pattern block is coupled to the transmitter.

(Step 2404 a) A pattern sequence is created from the “pattern” block and is transmitted onto the interconnect using the selected calibrate drive-timing-point.

(Step 2405 a) The pattern sequence is received in the second component and placed in storage.

(Step 2406 a) Control the “adjust” logic so the transmitter uses a normal (TX) drive-timing-point.

(Step 2407 a) Control the “adjust” logic so that the “normal path” to the transmitter is enabled.

(Step 2408 a) Resume normal transmit operations.

Note that receive operations could continue during this process except when the calibration pattern is actually being transmitted on the interconnect. In particular, the component could receive while its transmitter is changing the drive-timing-point between the normal and calibrate values. The second set of steps for the calibration process would consist of:

(Step 2401 b) The pattern sequence in storage is transmitted onto the interconnect by the second component.

(Step 2402 b) The pattern sequence is received using the normal (RX) sample-timing-point.

(Step 2403 b) The received pattern sequence is compared to the expected pattern sequence from the “pattern” block.

(Step 2404 b) The calibrate drive-timing-point (TXA/TXB, TX) is adjusted according to the results of the comparison.

Note that normal transmit and receive operations could continue during this process except when the calibration pattern is actually being received from the interconnect.

If reordering and overlapping of calibration steps is done, the overhead of the calibration process can be reduced, improving the effective signaling bandwidth of the system and reducing the worst case delay seen by latency-sensitive operations.

The reduction in overhead can also permit the periodic calibration process to be executed at a more frequent rate. The benefit is that this will compensate for sources of timing drift that change more rapidly. This will permit more of the bit time to be used for the transmitter drive time variation and the receiver sampling window, and less of the bit time will be needed for timing drift within the system.

FIG. 25 illustrates an example like that of FIG. 13, with the exception that the point to point bidirectional link of FIG. 13 is replaced with a multidrop link, coupling component 2500 to a plurality of components 2551, 2552. The multidrop link configuration can be applied in other configurations. In the representative example shown in FIG. 25, a first bidirectional component 2500 and a plurality of other bidirectional components 2551, 2552 are connected in a point to multi-point configuration, or multipoint to multipoint configuration, with an interconnection medium referred to as Link 2502. Normal path 2510 acts as a source of data signals for normal operation of component 2500 during transmit operations. Normal path 2531 acts as a destination of data signals for component 2500, during normal receive operations. The calibration operations are interleaved, and re-ordered, in this embodiment with normal communications, as described above to improve throughput and utilization of the communication medium

The first bidirectional component 2500 includes a block 2505 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of transmit calibration patterns. A multiplexer block 2506 labeled “mux,” implemented for example using a logical layer or physical layer switch, enables the transmit calibration pattern set to be driven onto the link by the transmitter circuit 2503. The transmitter drive point can be adjusted by the block 2507 labeled “adjust”. In this embodiment, the adjust block 2507 includes storage for multiple parameter sets which are applied depending on the one of the other components 2551, 2552, . . . on the link to which the transmission is being sent. Component 2500 also has support for calibrating receiver 2524, including a block 2528 labeled “pattern”, which can consist of pattern storage or pattern generation circuitry, and which is used as a source of expected patterns for comparison with received patterns. A block 2529 labeled “compare” enables the received pattern set to be compared to the expected pattern set, and causes an adjustment to be made to either the transmitter or receiver. The receiver sample point can be adjusted by the block 2532 labeled “adjust”. In this embodiment, the adjust block 2507 includes storage for multiple parameter sets which are applied depending on the one of the other components 2551, 2552, . . . on the link from which the communication is being received. In the first component 2500, the compare block 2529 is used for analysis of both transmit and receive calibration operations, and is coupled to both the adjust block 2507 for the transmitter, and adjust block 2532 for the receiver. In the example of FIG. 25, the receiver sample point and transmitter drive point of the first bidirectional component 2500 are adjustable. The other components 2551, 2552, . . . are implemented as described with reference to FIG. 13 without adjustment resources, in this example, and not described here. In alternative embodiments, the components 2551, 2552, . . . on the link may be provided with adjustment and calibration resources, as described for other embodiments above.

While the present invention is disclosed by reference to the preferred embodiments and examples detailed above, it is to be understood that these examples are intended in an illustrative rather than in a limiting sense. It is contemplated that modifications and combinations will readily occur to those skilled in the art, which modifications and combinations will be within the spirit of the invention and the scope of the following claims. 

We claim:
 1. A memory controller integrated circuit, comprising: a receiver to sample data arriving at the memory controller integrated circuit from a memory device, the receiver to sample the data at a sampling instant; logic to establish an operational value for the sampling instant, wherein the operational value is established during a calibration phase; and logic to compensate for drift between the operational value and timing associated with data transmitted by the memory device, and to update the operational value for the sampling instant in response to drift detected subsequent to establishment of the operational value.
 2. The memory controller integrated circuit of claim 1, wherein the logic to establish the operational value includes logic to vary the sampling instant, while the receiver is to sample the data, to responsively identify a data window, and logic to establish the operational value dependent on timing of the data window.
 3. The memory controller integrated circuit of claim 2, wherein: the logic to establish the operational value includes logic to transmit a symbol pattern to the memory device during the calibration phase; the receiver is to, during the calibration phase, sample a sequence of values received back from the memory device; the logic to establish the operational value includes logic is to compare the symbol pattern and the sequence to detect mismatch; and the logic to vary the sampling instant to identify the data window is to identify the data window dependent on detected mismatch.
 4. The memory controller integrated circuit of claim 3, wherein the logic to establish the operational value includes a pseudorandom bit pattern generator, and where the data pattern comprises a pseudorandom bit pattern of at least 2⁷−1 bits.
 5. The memory controller integrated circuit of claim 1, wherein the logic to establish the operational value for the sampling instant is to detect occurrence of at least one edge, at the receiver, associated with a transition between data values, and to establish the operational value for the sampling instant dependent on timing of the at least one edge.
 6. The memory controller integrated circuit of claim 5, wherein the logic to establish the operational value for the sampling instant is to detect occurrence of two different edges, at the receiver, associated with a data symbol period of data received at the receiver, and to establish the operational value for the sampling instant dependent on timing of each of the two different edges.
 7. The memory controller integrated circuit of claim 6, wherein the logic to establish the operational value for the sample instant is to establish the operational value for the sampling instant at an approximate center point between timing of the two different edges.
 8. The memory controller integrated circuit of claim 7, wherein the logic to compensate for drift and update the operational value includes logic to periodically identify variation in a timing point associated with the data induced by temperature change and to update the operational value to track said variation.
 9. A memory controller integrated circuit, comprising: a receiver to sample data arriving at the memory controller integrated circuit from a memory device, the receiver to sample the data at a sampling instant; logic to establish an operational value for the sampling instant, wherein the operational value is established during a calibration phase; and logic to compensate for drift between the operational value and timing associated with data transmitted by the memory device, and to update the operational value for the sampling instant in response to the drift detected after establishment of the operational value; wherein the logic to establish the operational value is to detect occurrence of at least one edge, at the receiver, associated with a transition between data values received during the calibration phase, and to establish the operational value for the sampling instant dependent on timing of the at least one edge.
 10. The memory controller integrated circuit of claim 9, wherein the logic to compensate for drift and update the operational value includes logic to periodically identify variation in a timing point associated with the data and to update the operational value to track said variation.
 11. The memory controller integrated circuit of claim 9, wherein the logic to establish the operational value for the sampling instant is to detect occurrence of two different edges, at the receiver, associated with a data symbol period of data received at the receiver, and to establish the operational value for the sampling instant dependent on timing of the two different edges.
 12. The memory controller integrated circuit of claim 11, wherein the logic to establish the operational value for the sample instant is to establish the operational value for the sampling instant at an approximate center point between timing of the two different edges.
 13. The memory controller integrated circuit of claim 9, wherein the logic to establish the operational value includes logic to vary the sampling instant, while the receiver is to sample the data, to responsively identify a data window, and logic to establish the operational value dependent on timing of the data window.
 14. The memory controller integrated circuit of claim 13, wherein: the logic to establish the operational value includes logic to transmit a symbol pattern to the memory device during the calibration phase; the receiver is to, during the calibration phase, sample a sequence of values received back from the memory device; the logic to establish the operational value includes logic is to compare the symbol pattern and the sequence to detect mismatch; and the logic to vary the sampling instant to identify the data window is to identify the data window dependent on detected mismatch.
 15. The memory controller integrated circuit of claim 13, wherein the logic to establish the operational value includes a pseudorandom bit pattern generator, and where the symbols comprise a pseudorandom bit pattern of at least 2⁷−1 bits.
 16. A method of operating a memory controller integrated circuit, comprising: sampling data arriving at the memory controller integrated circuit from a memory device according to sampling instant; establishing an operational value for the sampling instant, wherein the operational value is established during a calibration phase; and compensating for drift between the operational value and timing associated with data transmitted by the memory device, and updating the operational value for the sampling instant in response to drift detected subsequent to establishment of the operational value.
 17. The method of claim 16, wherein establishing the operational value includes varying the sampling instant, while sampling the data, to responsively identify a data window, and establishing the operational value dependent on timing of the data window.
 18. The method of claim 17, wherein: establishing the operational value includes transmitting a symbol pattern to the memory device during the calibration phase; sampling, during the calibration phase, a sequence of values received back from the memory device; establishing the operational value includes comparing the symbol pattern and the sequence to detect mismatch; and identifying the data window is to identify the data window dependent on detected mismatch.
 19. The method of claim 16, wherein establishing the operational value for the sampling instant includes detecting occurrence of at least one edge, at the memory controller integrated circuit, associated with a transition between data values, and establishing the operational value for the sampling instant dependent on timing of the at least one edge.
 20. The method of claim 16, wherein compensating for drift and updating the operational value includes periodically identifying variation in a timing point associated with the data induced by temperature change and to updating the operational value to track said variation. 